RU2637174C1 - Method of determining dielectric permeability of dielectric materials - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: method of determining the dielectric permeability ε of a material consists in measurement of a geometric difference of lengths at a fixed resonator frequency without a sample and with a sample of the tested material Δ_L=L_T-L_TS, but on the basis of calculation of a difference in the electrical lengths of the resonator without a sample and with a sample of the tested material

. The method of determining the dielectric permeability in the volumetric waveguide resonator includes tuning of the resonator on resonance frequency without a sample of the tested material, placing the sample of the tested material in the resonator, tuning of the resonator on resonance frequency by moving a movable piston, recording of the indication of the sensor of the mobile piston movement and computation of dielectric permeability, differs in the fact that after the resonator tuning with the sample in a resonance the frequency is recorded on which the resonator with the sample is tuned according to which the dielectric permeability is calculated.

EFFECT: higher accuracy in determining dielectric permeability of the dielectric materials.

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Description

The invention relates to techniques for determining the dielectric constant of materials by the method of a cavity resonator.

A known method for determining the dielectric constant (ε) in a cavity resonator with a fixed resonant length, GOST R 8.623-2006 (in the new edition of GOST R 8.623-2015). Measurements by this method are performed as follows:

, соответствующую

- постоянной распространения в пустой части резонатора без образца для

, λ_кр=С⋅R - критическая длина волны в цилиндрическом волноводе для волны типа H₀₁,

, ν₀₁=3,832 - численное значение корня уравнения для функции Бесселя

при рассмотрении распространения волны H₀₁ в круглом волноводе;- adjust the resonator length L _T to the frequency

corresponding

- constant propagation in the empty part of the resonator without sample for

, λ _kr = С⋅R is the critical wavelength in a cylindrical waveguide for a wave of type H ₀₁ ,

, ν ₀₁ = 3.832 is the numerical value of the root of the equation for the Bessel function

when considering the propagation of the wave H ₀₁ in a circular waveguide;

- move the movable piston down and place a sample of material of thickness d in the resonator;

- return the movable piston to its original position, restoring the length L _T ;

, соответствующей

- постоянной распространения

;- tune the frequency downward until resonance appears at the frequency

corresponding to

- continuous distribution

;

- measure and record the frequency ƒ _{2 of the} resonator with a sample of the test material;

- calculate the dielectric constant by the formula:

- постоянная распространения в области расположения образца, преобразуют окончательно:Where

- the propagation constant in the area of the sample, finally transform:

The advantage of the method for determining ε at a fixed cavity length is the high accuracy of determining resonant frequencies, and the disadvantage is that the method implements non-identical conditions for the excitation of resonant oscillations due to the difference in the measurement frequencies of the empty resonator and resonator with the sample of material placed in it. The empty cavity length is determined at a frequency ƒ ₁ corresponding to β _V1 , and the resonator is measured with a sample of the tested material at a frequency ƒ ₂ corresponding to β _V2 , therefore, the measurement errors of the frequency ƒ _{1 of the} corresponding length L _T , as can be seen from formula (1) also affect the accuracy of determining the dielectric constant. In addition, during the operation of frequency tuning in the direction of decreasing, the frequency shift occurs over the range by a significant frequency until the resonance appears, while the conditions for the appearance of resonance oscillations change and there is no unambiguity in determining the desired resonance by the type of oscillation and the correspondence of its dielectric constant test material.

Closest to the claimed is a method for determining the dielectric constant (ε) in a cavity resonator at a fixed resonant frequency, GOST R 8.623-2006 (in the new edition of GOST R 8.623-2015). Measurements by this method are performed as follows:

, соответствующую

- постоянной распространения в пустой части резонатора без образца для

, λ_кр=С⋅R - критическая длина волны в цилиндрическом волноводе для волны типа H₀₁,

, ν₀₁=3,832 - численное значение корня уравнения для функции Бесселя

при рассмотрении распространения волны H₀₁ в круглом волноводе;- adjust the resonator by changing the length L _T to the frequency

corresponding

- constant propagation in the empty part of the resonator without sample for

, λ _kr = С⋅R is the critical wavelength in a cylindrical waveguide for a wave of type H ₀₁ ,

, ν ₀₁ = 3.832 is the numerical value of the root of the equation for the Bessel function

when considering the propagation of the wave H ₀₁ in a circular waveguide;

- move the movable piston down and place a sample of material of thickness d in the resonator;

- move the movable piston up, adjusting the resonator to resonance at a frequency ƒ ₀₁ corresponding to β _V1 ;

- record the readings of the displacement sensor of the movable piston L _TS ;

- calculate the dielectric constant by the formula

- постоянная распространения в области расположения образца.Where

- propagation constant in the area of the sample.

The advantage in the method of determining ε at a fixed frequency is the implementation of identical conditions for the excitation of resonant oscillations at the location of the communication holes when measuring the resonator without a sample and a resonator with a sample, and the disadvantage is that tuning the resonator to a resonant frequency requires high accuracy of the moving piston moving mechanism to tune to a fixed measurement frequency. To realize precise tuning of the resonator to a fixed frequency with high accuracy, a very high accuracy in measuring the length of the resonator is required. However, it is impossible to ensure accurate adjustment of the position of the movable piston corresponding to a preselected frequency using mechanical systems due to the inevitable backlash in the movement mechanism, as a result of which there are errors in the measurement of permittivity.

The aim of the invention is to improve the accuracy of determining the dielectric constant.

A method for determining the dielectric constant of dielectric materials in a volume waveguide resonator using a network analyzer, which includes tuning the resonator without a sample of the test material to the resonant frequency by moving the movable piston, placing the sample of the test material in the resonator, tuning the resonator to the resonant frequency of the resonator by moving the movable piston, recording the reading of the displacement sensor rolling piston and permittivity calculation, characterized in that after tuning the resonator with the sample to the resonant frequency fix the frequency at which the resonator with the sample is tuned.

For the proposed method for determining the dielectric constant in a volumetric waveguide resonator, the authors developed an algorithm for calculating the dielectric constant (ε), which consists in solving the equation:

,

,

, соответствующую

- постоянной распространения в пустой части резонатора без образца испытуемого материала для

;where L _T is the cavity length without a sample tuned to the frequency

corresponding

- constant propagation in the empty part of the resonator without a sample of the test material for

;

, ν₀₁=3,832 - численное значение корня уравнения для функции Бесселя

при рассмотрении распространения волны H₀₁ в круглом волноводе;λ _cr = С⋅R is the critical wavelength in a cylindrical waveguide for a wave of type H ₀₁ ,

, ν ₀₁ = 3.832 is the numerical value of the root of the equation for the Bessel function

when considering the propagation of the wave H ₀₁ in a circular waveguide;

d is the thickness of the sample of the test material;

, соответствующую

- постоянной распространения для

;L _TS - resonator length with a sample of the test material tuned to the frequency

corresponding

- continuous distribution for

;

- постоянная распространения в области расположения образца для

, а

.

- propagation constant in the area of the sample for

, but

.

In FIG. 1 shows a General view of a device that implements the inventive method.

The device for determining the dielectric constant includes a volume resonator 1, in the upper part of the housing of which there are devices for input and output of microwave energy. A movable piston is installed inside the volumetric cylindrical resonator with a minimum gap, shown in the drawing in two positions: in position 2 — for a resonator tuned to a resonator without a sample, and in position 3 — for a resonator tuned to a resonator with a sample 4. Measurement of the position of the resonance curve on the frequency axis carried out by the network analyzer 5. Moving the movable piston is carried out using the movement mechanism 6, and the measurement of the position of the movable piston is carried out by the meter 7. Management, collection of information II, the processing and display of information is carried out by the processor device 8.

A device that implements the claimed method for determining the dielectric constant, works as follows.

, соответствующую

- постоянной распространения в пустой части резонатора без образца испытуемого материала для

, λ_кр=С⋅R - критическая длина волны в цилиндрическом волноводе для волны типа H₀₁,

, ν₀₁=3,832 - численное значение корня уравнения для функции Бесселя

при рассмотрении распространения волны H₀₁ в круглом волноводе. Устанавливают необходимую для наблюдения резонанса полосу обзора.The set frequency is set on the network analyzer

corresponding

- constant propagation in the empty part of the resonator without a sample of the test material for

, λ _kr = С⋅R is the critical wavelength in a cylindrical waveguide for a wave of type H ₀₁ ,

, ν ₀₁ = 3.832 is the numerical value of the root of the equation for the Bessel function

when considering the propagation of wave H ₀₁ in a circular waveguide. Set the field of view necessary for observing resonance.

Set the resonator without a sample into resonance by moving the movable piston using mechanism 6 and record the readings of the displacement sensor of the movable piston 7 L _T in the device 8.

The thickness of the sample of the test material d is introduced into the device 8.

Using mechanism 6, the movable piston of the resonator is removed from the resonator, a sample of the test material 4 is placed on it and the piston is introduced into the resonator and the resonator with the sample is tuned to resonance at the resonant frequency, moving the movable piston and observing the resonance curve on the network analyzer 5.

, соответствующую

- постоянной распространения для

, с помощью анализатора цепей 5.In the device 8, the reading of the displacement sensor of the movable piston 7 L _TS and the frequency

corresponding

- continuous distribution for

using a network analyzer 5.

In the device 8, after collecting information about the measurement, the dielectric constant (ε) is calculated by the formula:

,

,

- постоянная распространения в области расположения образца для

, а

.

- propagation constant in the area of the sample for

, but

.

The authors conducted an experimental verification of the proposed method on the installation for measuring the dielectric constant in a cylindrical cavity resonator with a H _01n wave with a diameter of 50 mm tuned to a frequency f ₁ = 9.45 GHz, with a quality factor of Q = 27000, when measuring a standard sample of silicon dioxide glass with dielectric constant ε = 3.815 and dielectric loss tangent tanδ = 9⋅10 ^-5 .

During measurements, the resonator with the sample was tuned into the resonance by the moving piston with deviations from the initial length L _TS corresponding to the resonance frequency ƒ ₂ , and the deviation in length ΔL and the deviation in frequency Δƒ were recorded.

The proposed method for measuring the dielectric constant assumes that when the sample was introduced into the resonator, the cavity length and measurement frequency changed, which are fixed and used in the calculation. Instead of tuning to the resonant frequency, a frequency locking operation is introduced, to which the resonator with the sample is tuned, which reduces the accuracy requirements for setting the resonant frequency, but improves the accuracy of measuring the dielectric constant.

In FIG. 2 shows the relative deviations from the dielectric constant Δε as a percentage of Δƒ. From FIG. 2 it can be seen that with significant deviations in frequency Δƒ, more than 1 MHz, the change in dielectric constant was not more than 0.01%.

In FIG. Figure 3 shows the relative deviations from the value of the dielectric constant Δε as a percentage of the values of ΔL during measurements by the proposed method and for comparison, the measurements are carried out using the existing method for measuring the variation of the length of the resonator at a fixed measurement frequency. From FIG. 3 it can be seen that with increasing deviations along the ΔL length, the dielectric constant changes for the existing measurement method at a fixed frequency significantly increase to 0.146%, and for measurements according to the proposed method with a maximum deviation of 0.028 mm, they were no more than 0.01%.

, реализованной за счет фиксации частоты, на которую настроен резонатор с образцом, в отличии от известного способа, основанного на определении диэлектрической проницаемости ε материала по разности геометрических длин на фиксированной частоте резонатора без образца и с образцом испытуемого материала ΔL=L_T-L_TS.The inventive method consists in determining the dielectric constant e of the material based on the refinement of the calculation of the difference in the electric lengths of the resonator without a sample and with a sample of the test material

realized by fixing the frequency at which the resonator with the sample is tuned, in contrast to the known method based on determining the dielectric constant ε of a material by the difference in geometric lengths at a fixed frequency of the resonator without a sample and with the sample of the test material ΔL = L _T -L _TS .

Made in the inventive method for determining the dielectric constant of the changes in the measuring procedure can improve the accuracy of determining the dielectric constant of the sample of the test material in a cylindrical cavity resonator.

Claims (1)

A method for determining the dielectric constant in a volumetric waveguide resonator using a network analyzer, which includes tuning the resonator without a sample of the test material to the resonant frequency by moving the movable piston, placing the sample of the test material in the resonator, tuning the resonator to the resonant frequency of the resonator by moving the movable piston, fixing the reading of the moving piston moving sensor and calculating the dielectric constant, characterized in that after tuning the resonator with the sample m on the resonant frequency is fixed frequency at which the resonator is configured with the sample, and then it is used in the calculation of the dielectric constant.

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